Abstract: A magnetic resonance imaging system comprises a main magnet to apply a stationary magnetic field in a magnetic field zone that includes an examination zone A display is positioned within the magnetic field zone. The display is a multi-stable display in which individual pixels have several brightness states. Notably, the display is based on an e-ink technology.

Abstract: In a medical MRI apparatus, it is often desirable to have devices 62, 64 for communicating with or monitoring the patient 58 in the imaging volume 29 of the apparatus. Such devices need DC power or low-frequency connections with an area 70 outside the imaging volume. A device cable that does not interfere with the MRI magnetic fields is known per se. The invention proposes to fix the device cable in a groove 76 in the patient carrier 60 in such a manner that its strip-shaped conductors 78, 80 extend parallel to the field lines of the stationary field B of the apparatus. In this way, it is also possible to clip device carriers 72, 74 to the groove, thus supplying the devices with DC power or establishing an audio connection through the device cable in the groove.

Abstract: In a medical MRI apparatus, it is often desirable to have electronic devices 62, 64 for communicating with or monitoring the patient 58 in the imaging volume 29 of the apparatus. Such electronic devices should not interfere with the MRI electromagnetic fields because of the high sensitivity of such apparatus to field disturbances. According to the invention, a shielding housing for such devices is proposed, which is formed from customary printed circuit board (PCB). Such shielding does not influence the MRI fields if the shielding layer 98 is made of a material having a resistivity below 0.05 ?m, a thickness below 40 ?m and the overall surface area of the shielding layer is less than 100 cm2.

Abstract: In a medical MRI apparatus, it is often desirable to have devices 62, 64 for communicating with or monitoring the patient 58 in the imaging volume 29 of the apparatus. Such devices need DC power or low-frequency connections with an area 70 outside the imaging volume. A device cable that does not interfere with the MRI magnetic fields is known per se. The invention proposes to fix the device cable in a groove 76 in the patient carrier 60 in such a manner that its strip-shaped conductors 78, 80 extend parallel to the field lines of the stationary field B of the apparatus. In this way, it is also possible to clip device carriers 72, 74 to the groove, thus supplying the devices with DC power or establishing an audio connection through the device cable in the groove.

Abstract: A magnetic resonance apparatus includes a magnet system (2) for generating a steady magnetic field (H) in a measuring space (28), an RF receiver circuit (10, 14, 16) with an RF receiver coil (10) for receiving RF signals emitted by an object arranged in the measuring space, a monitor (22) with a liquid crystal display (LCD) display screen (44) for image display, and a central control unit (18) which is connected to the RF receiver circuit and to the monitor for control in such a manner that information is applied to the LCD display screen. In order to prevent disturbing RF signals, produced by the monitor (22), from affecting the information obtained via the RF receiver circuit (10, 14, 16), the central control unit (18) is arranged to control the monitor in such a manner that information is applied to the LCD display screen (44) only during periods in which the RF receiver circuit is not activated.

Abstract: The transmitter/measurement coil of a nuclear magnetic resonance tomography apparatus for medical diagnosis in which comparatively high Larmor frequencies are used, is divided into a number of parallel-connected subcoils. The self resonance frequency of the coil can thus be made substantially higher than the Larmor frequency, with the result that the coil will have a suitably improved quality factor at higher frequencies, and measurements can be performed with an acceptable signal-to-noise ratio.